Improved (<Emphasis Type="Italic">R</Emphasis>)-phenylacetylcarbinol production with <Emphasis Type="Italic">Candida utilis</Emphasis> pyruvate decarboxylase at decreased organic to aqueous phase volume ratios

The effect of decreasing the organic (octanol) to aqueous phase volume ratio was evaluated in a two-phase enzymatic process for (R)-phenylacetylcarbinol (PAC) production. Decreasing the ratio from 1:1 to 0.43:1 at 4°C increased PAC in the organic phase from 112 g/l to 183 g/l with a 10% improvement in overall productivity. Interestingly, the rate of enzyme (pyruvate decarboxylase) activity loss was unaffected by the reduced phase ratio over the reaction period (48 h). At 20°C and 0.43:1 phase ratio the organic phase PAC concentration increased to 212 g/l and the overall productivity increased by 30% although the PAC yield (based on pyruvate) declined by about 10% due to greater byproduct acetoin formation at the higher temperature. Product recovery in such a system is facilitated both by the higher PAC concentration and the reduced organic phase volume.     

Functional restoration of acoustic units and adult‐generated neurons after hypothalamic lesion

The hypothalamus of the adult ring dove contains acoustic units that respond to species‐specific coo vocalization. Loss of nest coo leads to unsuccessful breeding. However, the recovery of nest coo in some doves suggests that these units are capable of self‐renewal. We have previously shown that lesioning the hypothalamus generates the addition of new neurons at the lesioned area. In this study, we sought to determine whether lesion‐induced new neurons are involved in the recovery of coo‐responsive units. We systematically recorded electrical activity in the ventromedial nucleus (VMN) of the hypothalamus, before and after lesion, for varying periods up to 3 months. Recordings were made when the birds were at rest (spontaneous discharge) and when the birds were exposed to acoustic stimulations (evoked discharge). Concurrently, the lesioned area was monitored for changes in cell types by using bromodeoxyuridine (BrdU) to label newly divided cells and NeuN to identify mature neurons. For 1 month after lesion, there was no sign of electrical activity, and only BrdU‐labeled cells were present. When the first electrical activity occurred, it displayed abnormal spontaneous bursting patterns. The mature discharge patterns (both spontaneous and evoked) occurred after detection of BrdU⁺/NeuN⁺ double‐labeled cells 2–3 months postlesion and were similar to those found in intact and sham‐lesioned birds. Double‐labeled cells bore morphologic characteristics of a neuron and were confirmed with z‐stack analysis using confocal laser scanning microscopy. Moreover, double‐labeled cells were not stained for glial fibrillary acidic protein (GFAP), suggesting that they were neurons. The number of coo‐responsive units was significantly correlated with that of BrdU⁺/NeuN⁺ cells. Furthermore, the marker for recording sites revealed that coo‐responsive units were colocalized with BrdU⁺/NeuN⁺ cells. Taken together, the evidence strongly suggests that lesion‐induced addition of new neurons promotes the functional recovery of the adult hypothalamus. © 2004 Wiley Periodicals, Inc. J Neurobiol 60: 197–213, 2004     

Cell-specific cis-regulatory elements and mechanisms of non-coding genetic disease in human retina and retinal organoids

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N‐cadherin regulates the proliferation and differentiation of ventral midbrain dopaminergic progenitors

Adherens junction (AJ) between dopaminergic (DA) progenitors maintains the structure of ventricular zone and polarity of radial glia cells in the ventral midbrain (vMB) during embryonic development. However, it is unclear how loss of N‐cadherin might influence the integrity of the AJ and the process of DA neurogenesis. Here, we used conditional gene targeting approaches to perform the region‐specific removal of N‐cadherin in the neurogenic niche of DA neurons in the vMB. Removal of N‐cadherin in the vMB using Shh‐Cre disrupts the AJs of DA progenitors and radial glia processes in the vMB. Surprisingly, loss of N‐cadherin in the vMB leads to a significant expansion of DA progenitors, including those expressing Sox2, Ngn2, and Otx2. Cell cycle analyses reveal that the cell cycle exit in the progenitor cells is decreased in the mutants from E11.5 to E12.5. In addition, the efficiency of DA progenitors in differentiating into DA neurons is decreased from E10.5 to E12.5, leading to a marked reduction in the number of DA neurons at E11.5, E12.5, and E17.5. Loss of N‐cadherin leads to the diffuse distribution of β‐catenin proteins, which are a critical component of AJ and Wnt signaling, from the AJ throughout the entire cytoplasm in neuroepithelial cells, suggesting that canonical Wnt signaling might be activated in the DA progenitors in vMB. Taken together, these results support the notion that N‐cadherin regulates the proliferation of DA progenitors and the differentiation of DA neurons through canonical Wnt‐β‐catenin signaling in the vMB. © 2013 Wiley Periodicals, Inc. Develop Neurobiol 73: 518–529, 2013     

Retinal ganglion cell dendritic development and its control

The way in which central neurons acquire their complex and precise dendrite arbors is of considerable developmental interest. Using retinal ganglion cells (RGCs) as a model, the mechanisms that pattern dendritic development are beginning to emerge. As in other systems, final dendrite phenotype is achieved by a mixture of intrinsic and extrinsic determinants. The extrinsic determinants of RGC dendrite shape reflect the anatomical constraints of producing a paracrystalline mosaic of arbors that laminates the inner plexiform layer of the retina. In this article, the key features of RGC dendrite development are reviewed. The emerging molecular mechanisms behind dendritic laminar segregation and “dendritic competition” are described. The role of afferent extrinsic influences are contrasted with those of retrograde, activity-dependent target influences that may regulate the final maturational phase of dendrite remodeling.     

PlexinA2 Forward Signaling through Rap1 GTPases Regulates Dentate Gyrus Development and Schizophrenia-like Behaviors

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